Next generation easy-clean lenses by robust liquid-repellent nanotextures. This project aims to produce better performing self-cleaning lenses, which are less likely to get dirty and are easy to clean. It will develop water and oil repellent coatings with superior optical transparency and mechanical, solvent and UV stability for both hard coated and anti-reflection coated optical lenses. Engineering of stable, ultra-liquid repellent nanomaterials on transparent surfaces will create a foundation ....Next generation easy-clean lenses by robust liquid-repellent nanotextures. This project aims to produce better performing self-cleaning lenses, which are less likely to get dirty and are easy to clean. It will develop water and oil repellent coatings with superior optical transparency and mechanical, solvent and UV stability for both hard coated and anti-reflection coated optical lenses. Engineering of stable, ultra-liquid repellent nanomaterials on transparent surfaces will create a foundation of knowledge for the industrial development of the future generation of easy care coatings, with vast application potential.Read moreRead less
High yield adaptive laser nanomanufacturing system for photonic devices. This project aims at developing an entirely new nanofabrication platform combining adaptive beamshaping with highly accurate large area nanopositioner to simultaneously address the throughput and accuracy challenges in nanomanufacturing. The proposed prototype system and fabricated photonic chips have performance far surpassing the state-of-the-art. Through trial in the industrial best laser nanofabrication system, commerci ....High yield adaptive laser nanomanufacturing system for photonic devices. This project aims at developing an entirely new nanofabrication platform combining adaptive beamshaping with highly accurate large area nanopositioner to simultaneously address the throughput and accuracy challenges in nanomanufacturing. The proposed prototype system and fabricated photonic chips have performance far surpassing the state-of-the-art. Through trial in the industrial best laser nanofabrication system, commercial benefits can be fast tracked for Australian industry in the rapidly expanding nanomanufacturing field. The outcomes lead to a platform technology enabling broad impact and benefits to other high-tech applications requiring high precision and throughput, enhancing Australia’s leading position in advanced manufacturing.Read moreRead less
Electro-Optical Primers for Safe Use and Clean Manufacturing. Conventional primers contain a mechanically-sensitive primary explosive that is used to detonate the more stable propellant in a bullet. This project aims to address the health and environmental impacts of heavy metals in current primers by replacing them with benign, electrically or optically activated silicon-based materials. Modern semiconductor fabrication techniques will be used to develop safe and clean primers through cost-effe ....Electro-Optical Primers for Safe Use and Clean Manufacturing. Conventional primers contain a mechanically-sensitive primary explosive that is used to detonate the more stable propellant in a bullet. This project aims to address the health and environmental impacts of heavy metals in current primers by replacing them with benign, electrically or optically activated silicon-based materials. Modern semiconductor fabrication techniques will be used to develop safe and clean primers through cost-effective doping and deposition protocols. The expected outcomes of the project include a sovereign primer manufacturing capability for Australia. This will provide a significant strategic advantage and health benefits for law enforcement and defence personnel during live fire training and firing range exercises.Read moreRead less
Advanced lanthanide-doped nanomaterials for new-generation security inks. Current security labelling technologies using pattern coding (“barcoding”) and/or UV-excited phosphorescent inks are relatively easily counterfeited. The project aims to identify optimal design, fabrication and surface treatment of infrared-excited lanthanide nanoparticles for use as pigments in UV-curable polymer inks. This is expected to result in a new-generation of jet-printable security inks with ultimate capability f ....Advanced lanthanide-doped nanomaterials for new-generation security inks. Current security labelling technologies using pattern coding (“barcoding”) and/or UV-excited phosphorescent inks are relatively easily counterfeited. The project aims to identify optimal design, fabrication and surface treatment of infrared-excited lanthanide nanoparticles for use as pigments in UV-curable polymer inks. This is expected to result in a new-generation of jet-printable security inks with ultimate capability for multidimensional coding (using multiple luminescence wavelengths and lifetimes) and robust readability. Expected outcomes are world leadership in codable inks for secure labelling against counterfeiting, greatly enhancing both global ink-product sales and the value of Australian exports subject to product substitution.Read moreRead less
Novel Fuel Materials for Radiation-Free Proton-Boron Fusion Power Source. Laser proton-boron fusion reactions are a radiation-free nuclear energy source but are limited by a low reaction rate due to a lack of efficient fuel materials. This project aims to develop new fuel materials by synthesising isotope boron 11 enriched hydrogen borides and hydrogen adsorbed boron nitride nanosheets using our research experience in hydrogen storage and nanomateials synthesis. The expected outcomes include tw ....Novel Fuel Materials for Radiation-Free Proton-Boron Fusion Power Source. Laser proton-boron fusion reactions are a radiation-free nuclear energy source but are limited by a low reaction rate due to a lack of efficient fuel materials. This project aims to develop new fuel materials by synthesising isotope boron 11 enriched hydrogen borides and hydrogen adsorbed boron nitride nanosheets using our research experience in hydrogen storage and nanomateials synthesis. The expected outcomes include two new hydrogen storage nanomaterials, the associated new synthesis technologies, and a clean and safe nuclear power source, which helps to reduce carbon dioxide emissions.Read moreRead less
Highly Efficient Solar Window Technology Enabled by Quantum Dots. The transition to zero-greenhouse gas emitting buildings is hindered by the lack of efficient energy generating building components with good aesthetics. This project will develop integrated solar windows that can effectively convert the facades of urban buildings into energy generation sites, enabled by our nanomaterials having outstanding light emission efficiencies of over 90%, accompanied by our advanced light guiding strategi ....Highly Efficient Solar Window Technology Enabled by Quantum Dots. The transition to zero-greenhouse gas emitting buildings is hindered by the lack of efficient energy generating building components with good aesthetics. This project will develop integrated solar windows that can effectively convert the facades of urban buildings into energy generation sites, enabled by our nanomaterials having outstanding light emission efficiencies of over 90%, accompanied by our advanced light guiding strategies and innovative PV cell integration. This next generation technology can reduce the electricity cost and increase renewable energy adoption, placing Australia in a competitive position in the billion-dollar building integrated photovoltaic market whilst also contributing to decarbonising electricity generation.Read moreRead less
Scalable and reversible computing with integrated nanomechanics. This project aims to build the first scalable computing architecture based on nanomechanical motion, integrated on a silicon chip and proven in harsh environments. This could extend the performance of computers in space and high-radiation environments, e.g. allowing robust satellite stabilisation. The project will leverage our know-how in phononics and nanofabrication to enable previously unprecedented control of nanomechanical mot ....Scalable and reversible computing with integrated nanomechanics. This project aims to build the first scalable computing architecture based on nanomechanical motion, integrated on a silicon chip and proven in harsh environments. This could extend the performance of computers in space and high-radiation environments, e.g. allowing robust satellite stabilisation. The project will leverage our know-how in phononics and nanofabrication to enable previously unprecedented control of nanomechanical motion, and exquisitely low energy dissipation. It aims to construct a nanomechanical processor capable of digital servo control, built from nanomechanical waveguides, transistors, logic gates and analogue-to-digital converters. It will also develop reversible logic gates, a key step towards ultralow-power computing.Read moreRead less
Scalable high-density hydrogen storage by nano-bubbles in layered materials. Stable and low-cost hydrogen storage and transportation are cornerstones of a global hydrogen economy. This project aims to advance a novel hydrogen storage technology based on highly pressurised nano-bubbles in layered materials. The project expects to expand our fundamental knowledge of the interactions between hydrogen and layered materials. Expected outcomes include a hydrogen storage technology that exhibits a rema ....Scalable high-density hydrogen storage by nano-bubbles in layered materials. Stable and low-cost hydrogen storage and transportation are cornerstones of a global hydrogen economy. This project aims to advance a novel hydrogen storage technology based on highly pressurised nano-bubbles in layered materials. The project expects to expand our fundamental knowledge of the interactions between hydrogen and layered materials. Expected outcomes include a hydrogen storage technology that exhibits a remarkable energy density, high stability and low cost. This should provide significant benefits, such as improving the capacity and robustness of low-cost hydrogen storage and transportation, reducing energy costs and making hydrogen energy a more accessible and sustainable clean energy source for Australia.Read moreRead less
Advanced protective coatings for thermal energy management devices. This project aims to develop new nanomaterial coatings and advanced plasma coating technology to address the global issue of e-waste caused by short lifespan thermal energy management devices (TEMDs) used in energy (solar, wind, oil), transport (aerospace, automotive, marine) and industrial (manufacturing, mining) sectors. The project expects to overcome issues of erosion and corrosion of TEMDs and toxic coating methods by devel ....Advanced protective coatings for thermal energy management devices. This project aims to develop new nanomaterial coatings and advanced plasma coating technology to address the global issue of e-waste caused by short lifespan thermal energy management devices (TEMDs) used in energy (solar, wind, oil), transport (aerospace, automotive, marine) and industrial (manufacturing, mining) sectors. The project expects to overcome issues of erosion and corrosion of TEMDs and toxic coating methods by developing new nanomaterial coatings and innovative plasma coating technology. This should provide significant benefits such as improved sustainability of TEMDs with improved corrosion resistance and durability, as well as new manufacturing products and processes that have far reaching economic benefits for Australia.Read moreRead less
Development and application of WO3-Mica Multifunctional Nanocomposites . This project aims to develop innovative techniques to produce advanced tungsten oxide/metal oxide/mica composites for paint applications. The findings will be used to develop pearlescent paints for diverse applications in a range of industries, with the potential for huge benefits in improving the value of metal oxides and mica. The findings will be useful in the development of other new materials and provide a foundation f ....Development and application of WO3-Mica Multifunctional Nanocomposites . This project aims to develop innovative techniques to produce advanced tungsten oxide/metal oxide/mica composites for paint applications. The findings will be used to develop pearlescent paints for diverse applications in a range of industries, with the potential for huge benefits in improving the value of metal oxides and mica. The findings will be useful in the development of other new materials and provide a foundation for new applications such as photochromic and self-cleaning paints. This will generate opportunities to develop and apply advanced knowledge to solve significant problems in industry, leading to national economic growth by adding high values of mineral resources in Australia.
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